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Predictive Value of Human Leukocyte Antigen Class II Typing for the Development of Islet Autoantibodies and Insulin-Dependent Diabetes Postpartum in Women with Gestational Diabetes¹

Laboratory for Immunogenetics, Ludwig Maximilians University (K.M.F., E.K., E.D.A.), and the Third Medical Department, Krankenhaus München-Schwabing, and Diabetes Research Institute (K.M.F., A.-G.Z.), 80804 Munich, Germany

Address all correspondence and requests for reprints to: Priv.-Doz. Dr. Anette-G. Ziegler, Krankenhaus München-Schwabing, Diabetes Research Institute, Kölner Platz 1, 80804 Munich, Germany. E-mail: anziegler{at}lrz.uni-muenchen.de

	Abstract

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Gestational diabetes mellitus (GDM) is a risk factor for the development of insulin-dependent diabetes mellitus (IDDM) and noninsulin-dependent diabetes mellitus postpartum. To evaluate whether there is any association of human leukocyte antigen (HLA) class II alleles (DR and DQ) with GDM and the postpartum development of IDDM, we analyzed 184 women with GDM from Germany for HLA class II alleles, islet autoantibodies [islet cell autoantibodies (ICA), glutamic acid decarboxylase autoantibodies (GADA), and protein tyrosine phosphatase IA-2 autoantibodies (IA-2A), and the postpartum development of diabetes. No elevation in the frequency of any HLA class II alleles was observed in GDM patients compared to 254 nondiabetic unrelated subjects. DR3 allele frequency was significantly increased in 43 women with islet autoantibodies [corrected P value (P_c) = 0.02], in particular in those with GADA (P_c = 0.002), or in the 24 women who developed IDDM postpartum (P_c = 0.005). In women with GADA, DR4 and DQB1_*0302 were significantly elevated (P_c = 0.009). Twenty-five (59.5%) islet antibody-positive women and 17 (74%) women who developed IDDM postpartum had a DR3- or DR4-containing genotype. The cumulative risk to develop IDDM within 2 yr postpartum in GDM women with either DR3 or DR4 was 22% compared to 7% in women without those alleles (P = 0.02) and rose to 50% in the DR3- or DR4-positive women who had required insulin during pregnancy (P = 0.006). Combining the determination of susceptible HLA alleles (DR3, DR4) with islet autoantibody measurement increased the sensitivity of identifying GDM women developing postpartum IDDM to 92%, but did not improve risk assessment above that achieved using GADA measurement alone, which was the strongest predictor of IDDM. These results indicate that women with GDM who have islet autoantibodies at delivery or develop IDDM postpartum have HLA alleles typical of late-onset type 1 diabetes, and that both HLA typing and islet antibodies can predict the development of postpartum IDDM.

	Introduction

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GESTATIONAL diabetes mellitus (GDM) is a heterogeneous disorder of different etiologies and is associated with a high risk of noninsulin-dependent diabetes (NIDDM) as well as insulin-dependent diabetes (IDDM) postpartum. We have recently reported that islet autoantibody screening at delivery is a useful strategy to identify the subgroup of women with a slowly evolving form of autoimmune diabetes who develop insulin dependency within a few years after pregnancy (1).

Autoimmune type 1 diabetes is also associated with specific human leukocyte antigen (HLA) DR3- and DR4-containing haplotypes, and the risk is particularly high for DR3/4 heterozygous or DR4/4-DQB1_*0302/_*0302 homozygous individuals (reviewed in Refs. 2, 3). Although almost all pediatric IDDM patients have DR3 and/or DR4, these haplotypes are less prevalent in patients with diabetes onset after 15 yr of age (4). Furthermore, it has been suggested that DR3 is associated with a more slowly progressive form of IDDM (5). Few data on genetic markers in gestational diabetes exist (6, 7, 8, 9, 10). The aim of the present study was to analyze the frequency of HLA class II alleles and genotypes in patients with GDM and to determine whether HLA markers can predict the development of islet autoantibodies and IDDM postpartum. We found that GDM per se is not associated with specific HLA class II alleles, that the proportion of GDM women with islet autoantibodies is highest in those who carry the DR3 or DR4 allele, and that women with a DR3 or DR4 genotype have a higher risk to develop IDDM after pregnancy compared to non-DR3/non-DR4 patients.

	Subjects and Methods

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Patients with gestational diabetes mellitus

From 1989–1996, 481 Caucasian women with GDM were recruited in the context of the multicenter prospective study BABYDIAB in different hospitals of Germany. They were tested for islet autoantibodies at delivery and were followed for the development of IDDM or NIDDM postpartum. All subjects were recruited consecutively on admission to delivery in a nonselective fashion, as described in detail previously (1). Diagnosis of GDM was made according to the German Diabetes Association, using an oral glucose tolerance test with a 75-g glucose load. GDM was diagnosed if 2 of 3 capillary blood glucose values exceeded the following limits: more than 5.0 mmol/L (fasting) before oral glucose tolerance test, more than 10.6 mmol/L after 60 min, and more than 8.9 mmol/L after 120 min. All participating centers (1) were asked to follow the therapeutic guidelines for the treatment of GDM recommended by the Diabetes and Pregnancy Study Group of the German Diabetes Association to ensure a uniform therapeutic strategy among the participating hospitals. In accordance with these guidelines, insulin therapy was required if capillary blood glucose levels, during a diet regimen for at least 1 week, exceeded the following limits: more than 5.0 mmol/L before and more than 7.8 mmol/L at 60 min and more than 6.7 mmol/L at 120 min after meals. After delivery, patients were invited to participate in a follow-up examination at 9 months, 2 yr, and 5 yr postpartum, when oral glucose tolerance tests were performed and venous blood samples for HLA typing were requested. Of all 481 women enrolled, 332 participated in at least 1 follow-up visit with an oral glucose tolerance test postpartum (Fig. 1). Of those, 184 women also accepted blood drawing for HLA typing. They were included into the analysis of this manuscript (median age, 31.4 yr). Of all of the women enrolled, 149 were lost to follow-up because they had moved to an unknown address or refused participation. As shown in Fig. 1, there was no major difference in islet autoantibody frequency or frequency of IDDM, NIDDM, or impaired glucose tolerance (IGT) between GDM women with or without HLA typing. Furthermore, no differences in baseline characteristics (age at delivery, body mass index before pregnancy, or gestation duration) between women who were HLA typed compared to those for whom HLA typing was not available were found (z test). Of the 184 women included in the study, 120 were treated with diet alone [White classification (11) GDM-A], and 64 were treated with insulin (White GDM-B) during pregnancy. Postpartum diabetes was diagnosed according to WHO criteria (2 h blood glucose level, >200 mg/dL = >11.1 mmol/L). Diabetes was classified as insulin dependent (IDDM) in the presence of ketoacidosis or as requiring insulin treatment not only to control hyperglycemia and symptoms but to prevent the spontaneous occurrence of ketoacidosis. This classification was based upon clinical evaluation and not influenced through antibody measurement or HLA typing. Due to instructions given to us by the ethical approval board of the Bayerische Landesärztekammer, clinicians and patients were not informed about these results. Women with IGT postpartum (n = 12) were not considered diabetic in this analysis. The median follow-ups from the day of delivery to postpartum diabetes onset and to the last contact with the patient were 0.8 yr (0–3.5 yr) and 3.0 yr (1.1–7.7 yr), respectively. Informed consent was obtained from all patients who participated in the study.

View larger version (26K): [in this window] [in a new window]   Figure 1. Flow diagram showing HLA ascertainment in women with GDM recruited at delivery and followed postpartum for the development of IDDM, NIDDM, or IGT. The median follow-up times after delivery to diabetes onset or last contact were 2.48 and 2.5 yr, respectively, for women who accepted and refused HLA typing.

HLA class II allele frequencies were also determined in 254 nondiabetic unrelated control subjects from the same ethical background and region of Germany (median age, 39.5 yr; 50% male).

HLA typing

HLA class II alleles, HLA-DRB1, HLA-DQA1, and HLA-DQB1, were determined using PCR-amplified DNA and nonradioactive oligonucleotide probes (sequence-specific oligonucleotide typing). The isolation of the genomic DNA was performed from fresh peripheral blood cells (ethylenediamine tetraacetate-blood) by the salting out procedure described in the 11th Workshop report (12). Genomic DNA (1 µg) was amplified by PCR in a 100-µL reaction volume using 25 pmol primers (12), 20 nmol deoxy-NTPs, 2.5 U Taq polymerase, and buffer [10 mmol/L Tris-HCl (pH 8.3), 50 mmol/L KCl, 1.5 mmol/L MgCl₂, and 0.001% gelatin]. For the dot blot hybridization the amplified DNA (2 µL) was spotted onto nylon membranes (Boehringer Mannheim, Mannheim, Germany) and hybridized with 15 DRB generic and 17 DQA- and 20 DQB-specific oligonucleotides, respectively (12). The hybridized oligonucleotides, 3'-end labeled with digoxygenin-11–2',3'-dideoxyuridine-5'-triphosphate (Boehringer Mannheim) were detected using anti-digoxigenin-AP Fab (Boehringer Mannheim), and visualization was achieved with the chemiluminescent substrate CSPD (Boehringer Mannheim) (13). The HLA-DRB1, HLA-DQA1, and HLA-DQB1 alleles were named according to the nomenclature of 1996 (14). The alleles DQA1_*03011 and _*0302 were indistinguishable by sequence-specific oligonucleotide typing and were therefore referred to as DQA1_*03. Also, the alleles DQB1_*0201 and _*0202 were indistinguishable and were referred to as DQB1_*02. In 179 women, complete HLA genotyping (DR, DQA, and DQB) was available. In five women (one with elevated islet autoantibodies), complete typing could not be obtained (one with missing DQA, one with missing DR and DQA, two with missing DQB, and one with missing DR alleles).

Islet autoantibody determination

Autoantibodies to glutamic acid decarboxylase (GADA), the protein tyrosine phosphatase IA-2 (IA2A), and islet cells (ICA) were analyzed as previously described (1, 15). The upper limit of normal was defined by the 99th percentile of antibody levels determined in nondiabetic women at delivery (GADA, 13 U; IA2A, 5 U; ICA, 5 Juvenile Diabetes Foundation units) (1). Antibody assays were entered into the international Antibody Proficiency Program (organized by N. MacLaren, Gainesville, FL). The GADA assay achieved a specificity of 100% and a sensitivity of 94% (Third Workshop), the IA2A assay achieved specificities of 100% and 100% (First Workshop), and the ICA assay achieved specificities of 100% and 67% (NinthWworkshop), respectively.

Statistical analysis

Allele and genotype frequencies were determined for patients and the control group. If only one allele could be detected, we assumed that the subject was homozygous for this allele. P values were determined by Fisher’s exact test and were corrected for the number of comparison made (P_c; DRB1, P_c = p_uncorr x 11; DQA1, P_c = p_uncorr x 9; DQB1, P_c = p_uncorr x 14). Kaplan-Meier life table analysis was used to determine the cumulative risk of diabetes postpartum. Follow-up started with the day of delivery and ended with diabetes or the last contact with the patient. Five women with GDM remained insulin dependent from the day of delivery, with a calculated follow-up time of zero (life table curves for these cases start below 100%). Differences in survival experiences were determined by log-rank test in the Statistical Package for Social Science (SPSS, Inc., Chicago, IL). Ninety-five percent confidence intervals (CI) for cumulative risk were calculated from the SE thereof.

	Results

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HLA class II allele frequencies in GDM

Table 1 summarizes allele frequencies of HLA-DRB1, -DQA1, and -DQB1 in women with GDM compared to control subjects. No significant differences in the distribution of allele frequencies were observed between cohorts.

Of women with GDM, 43 had at least 1 elevated islet autoantibody (GADA, IA2A, or ICA) at delivery. In this group a significant increase in allele frequency of DRB1_*03 was observed compared to that in the control population (23.8% vs. 10.6%; P_uncorr = 0.001; P_c = 0.02; Table 1). After stratification for DR3, the frequency of DR4 was also significantly increased (P_uncorr = 0.007). In autoantibody-negative women, the frequency distribution of HLA class II alleles was similar to that in control subjects (Table 1). Of all islet autoantibody-positive women with GDM, 24 (55.8%) had elevated GADA at delivery. In this population IDDM-associated alleles were even more prevalent (DR3, 32.6%; DR4, 32.4%; DQA1_*03, 34.8%; DQB1_*0302, 31.2%; P_c = 0.002, 0.009, 0.004, and 0.0003, respectively; Table 1). Twenty-five of the women with islet autoantibodies (59.5%) and 19 (82.6%) of those with GADA had a genotype with at least 1 DR3 or DR4 allele.

HLA class II allele and genotype frequencies in women with GDM who developed diabetes postpartum

Twenty-four women with GDM developed IDDM during follow-up postpartum (Table 2; median age 31 years). In this subgroup of women with postpartum IDDM, a higher frequency of DRB1_*03 was detected compared to that in control subjects (30.4% vs. 10.6%; P_c = 0.005; Table 1). After stratification for DR3, a significant increase in DR4 in GDM women who developed IDDM postpartum was also observed [uncorrected P (P_uncorr) = 0.02]. Seventeen (73.9%) of the 24 women who developed IDDM postpartum had a genotype with at least 1 DR3 or DR4 allele (Table 2); none, however, was DR3/4 heterozygous. All but 1 women with DR4 had the DR4-DQB1_*0302 haplotype. Six women with GDM who developed IDDM postpartum had a DR2-containing genotype and four of those included the "protective" DQB1_*0602 allele rarely found in patients with IDDM (16). In the group of patients with GDM who developed NIDDM postpartum (median age, 32 yr), no specific allele was elevated (Table 1).

Of all women with GDM, 80 had a DR3- or DR4-containing genotype, whereas 102 were typed as non-DR3/non-DR4. The cumulative risk to develop IDDM within 2 yr postpartum was 20.9% (95% CI, 12–30) in women with DR3 or DR4 compared to 6.5% (95% CI, 1–12) in women without a DR3- or DR4-containing genotype (P = 0.002; Fig. 2). In DR3- or DR4-positive women with GDM who were treated with insulin during pregnancy (GDM-B), the 2-yr risk of IDDM was 47.7% (95% CI, 29–67) compared to 13.9% (95% CI, 1–27) in DR3- and DR4-negative GDM-B women (P = 0.007; Fig. 3A). The risk of IDDM in women with GDM who were treated with diet during pregnancy in contrast was relatively low, and no difference between genotypes was observed (Fig. 3B).

View larger version (16K): [in this window] [in a new window]   Figure 2. Cumulative life table risk of IDDM postpartum in women with GDM relative to the presence (solid line) or absence (broken line) of a DR3- or DR4-containing genotype. The cumulative risk to develop IDDM within 2 yr postpartum was 20.9% (95% CI, 12–30) in women with DR3 or DR4 compared to 6.7% (95% CI, 2–12) in women without a DR3 or DR4 allele (P = 0.002).

View larger version (17K): [in this window] [in a new window]   Figure 3. A and B, Cumulative life table risk of IDDM relative to the presence (solid line) or absence (broken line) of a DR3- or DR4-containing genotype in women with GDM-B (A) and women with GDM-A (B). The cumulative life table risk was significantly increased in women with GDM-B who carried a DR3- or DR4-containing genotype (A, solid line; 2-yr risk, 47.7%; 95% CI, 29–67).

View larger version (18K): [in this window] [in a new window]   Figure 4. A and B, Cumulative life table risk of IDDM relative to the presence (solid line) or absence (broken line) of a DR3- or DR4-containing genotype in women with islet autoantibodies at delivery (A) and women without islet autoantibodies (B). The cumulative life table risk was increased in women with islet autoantibodies (A vs. B), particularly in those women who had islet autoantibodies and, in addition, a DR3- or DR4-containing genotype (A, solid line; 2-yr risk, 44.3%; 95% CI, 25–64).

View larger version (19K): [in this window] [in a new window]   Figure 5. Cumulative life table risk of IDDM in GDM women with islet autoantibodies (Ab+) relative to the presence or absence of GADA and the presence (solid lines) or absence (broken lines) of a DR3- or DR4-containing genotype. The cumulative life table risk to develop IDDM within 2 yr postpartum was 52.6% (95% CI, 30–75) for patients with GADA and the DR3 or DR4 genotype (GADA+/DR3 or DR4) and 50% (95% CI, 1–99) for patients with GADA and a non-DR3/non-DR4 genotype (GADA+/non-DR3/non-DR4); it was lower in patients without GADA but with other islet autoantibodies (ICA or IA2A; GADA-/Ab+) regardless of the presence (0%) or absence (18.0%; 95% CI, 0–30) of a DR3- or DR4-containing genotype.

	Discussion

Top Abstract Introduction Subjects and Methods Results Discussion References

Other studies have also reported that the distribution of HLA class II alleles in women with GDM or IGT during pregnancy does not differ from that in pregnant women with normal glucose tolerance (6, 10, 17). As GDM is a heterogeneous disorder predisposing to the development of IDDM and NIDDM postpartum, it is not surprising that there is no increase in specific HLA alleles, in particular not of those associated with susceptibility to IDDM. Furthermore, women with GDM who develop IDDM later in life represent a subgroup of IDDM patients with a relatively slowly evolving form of diabetes and late onset of the disease. In these patients, in whom clinical symptoms are often not so pronounced, it has been shown that the prevalence of DR3- or DR4-positive genotypes is lower than that in patients with type 1 diabetes with onset of diabetes before puberty (8, 18). Caillat-Zucman and co-workers reported that 97% of children with onset of IDDM before 15 yr of age had a DR3- or DR4-containing genotype compared to 74% of patients with onset after 35 yr of age (4). In the present study, we found that the allele frequency of DR3 was significantly increased in women who developed IDDM postpartum compared to the background prevalence in the general population. We also observed that 74% of women who developed postpartum IDDM had a DR3- or DR4-positive genotype. These results are in accordance with previous studies (4, 6, 7, 8, 9, 10) and are remarkably similar to those obtained in the study of Caillat-Zucman, who investigated patients without preceding GDM. They indicate that the subgroup of patients with GDM who develop IDDM postpartum have typical HLA genotypes of late-onset IDDM.

Not only is the distribution of HLA alleles different between patients with childhood or adult-onset IDDM but so is the antibody profile. In adult patients with newly diagnosed IDDM or pretype 1 diabetes, GADA are the most prevalent antibodies, whereas in young subjects, IA-2A and insulin autoantibodies are more frequent (19). In women with GDM, we have previously shown that GADA are the most sensitive single antibody markers to predict the development of IDDM postpartum (1). We here demonstrate that in GDM, as found in IDDM (19, 20), they are strongly associated with the presence of DR3 in particular, but also with DR4 and DQB1_*0302.

Islet autoantibodies measured at delivery in women with GDM can predict the onset of IDDM postpartum with a risk correlating to the number of autoantibodies present in the patient’s serum (1). In this study, HLA markers of IDDM were also associated with an increased risk of progression to IDDM postpartum. This was particularly so for women who had required insulin treatment during pregnancy (GDM-B), in whom the risk of disease within 2 yr after pregnancy was 50% when they carried a DR3- or DR4-containing genotype. This suggests that HLA typing for the presence of DR3 or DR4 in women with GDM of White B could be used as an alternative to islet autoantibody testing to assess IDDM risk postpartum. Of women with postpartum IDDM, 74% had a DR3- or DR4-positive genotype, and a similar proportion (71%) had elevated islet autoantibodies. By combining antibody measurement and determination of susceptible HLA alleles (DR3, DR4), 92% of patients with progression to IDDM were identified, suggesting that the combination of both markers may increase sensitivity. Moreover, women without antibodies and without a DR3 or DR4 genotype had a low risk of developing IDDM (2.8%), indicating that HLA typing in antibody-negative women may be useful for excluding IDDM risk. In women with positive islet autoantibodies, in contrast, additional HLA typing was less informative. Here, the presence or absence of GADA seems to be the most important factor that determines diabetes risk independent of HLA genes. This implies that HLA provides susceptibility for antibodies, but has no major effect on the rate of progression to IDDM once antibodies are detectable.

We conclude that specific HLA alleles predispose to the development of diabetes-associated autoantibodies and type 1 diabetes postpartum. The measurement of antibodies, in particular GADA, appears to be the single most useful screen in women with GDM, but when islet autoantibody testing is not available, HLA typing for the presence or absence of DR3 or DR4 may be a useful strategy in women who required insulin during pregnancy. In islet autoantibody-negative women, HLA typing may also be useful to increase either sensitivity (presence of HLA-DR3 or -DR4) or specificity (absence of HLA-DR3 or -DR4).

	Acknowledgments

 
We thank J. Vordemann, A. Schimmel, M. Dübell, and I. Zöbisch for expert technical assistance, and G. Brünnler for statistical advice in the HLA analysis. We also thank all obstetric departments and family doctors in Germany who participated in the study for the recruitment and the follow-up attendance of the women with GDM.

	Footnotes

 
¹ This work was supported by grants from the Bundesministerium für Forschung, Bildung und Technologie (BMBF 01KD89030 and 1KD9601; to A.-G.Z.), and the Sonderforschungsbereich 217 Projekt C11 (to E.D.A.). This work is part of the dissertation of K.F. at the Ludwig Maximilians University (Munich, Germany).

Received December 28, 1998.

Revised March 12, 1999.

Accepted March 23, 1999.

	References

Top Abstract Introduction Subjects and Methods Results Discussion References

 

1. Füchtenbusch M, Ferber K, Standl E, Ziegler A-G. 1997 Prediction of type 1 diabetes postpartum in patients with gestational diabetes mellitus by combined islet cell autoantibody screening. Diabetes. 46:1459–1467.[Abstract]
2. She J-X. 1996 Susceptibility to type I diabetes. HLA-DQ and DR revisited. Immunol Today. 17:323–329.[CrossRef][Medline]
3. Tisch R, McDevitt H. 1996 Insulin-dependent diabetes mellitus. Cell. 85:291–297.[CrossRef][Medline]
4. Caillat-Zucman S, Garchon HJ, Timsit J, et al. 1992 Age-dependent HLA genetic heterogeneity of type 1 insulin-dependent diabetes mellitus. J Clin Invest. 90:2242–2250.
5. Ludvigsson J, Samuelsson U, Beauforts C, et al. 1986 HLA-DR 3 is associated with a more slowly progressive form of type I (insulin-dependent) diabetes. Diabetologia. 29:207–210.[CrossRef][Medline]
6. Rubinstein P, Walker M, Krassner J, et al. 1981 HLA antigens and islet cell antibodies in gestational diabetes. Hum Immunol. 3:271–275.[CrossRef][Medline]
7. Freinkel N, Metzger BE, Phelps RL, et al. 1985 Gestational diabetes mellitus. Heterogeneity of maternal age, weight, insulin secretion, HLA antigens, and islet cell antibodies and the impact of maternal metabolism on pancreatic B-cell and somatic development in the offspring. Diabetes 34(Suppl 2):1–7.
8. Møller-Jensen B, Buschard K, Buch I, et al. 1987 HLA associations in insulin-dependent diabetes mellitus during pregnancy. Acta Endocrinol (Copenh). 116:387–389.[Abstract/Free Full Text]
9. Owerbach D, Carnegie S, Rich C, Metzger BE, Freinkel N. 1987 Gestational diabetes mellitus is associated with HLA-DQ ß-chain DNA endonuclease fragments. Diabetes Res. 6:109–112.[Medline]
10. Damm P, Kühl C, Buschard, et al. 1994 Prevalence and predictive value of islet cell antibodies in women with gestational diabetes. Diabetic Med. 11:558–563.[Medline]
11. White P. 1971 Pregnancy and diabetes. In: Marble A, White P, Bradley RF, eds. Joslin’s diabetes mellitus. Philadelphia: Lea & Febinger; 581–588.
12. Kimura A, Sasazuki T. 1992 Eleventh international histocompatibility workshop reference protocol for the HLA DNA-typing technique. In: Tsuji K, Aizawa M, Sasazuki T, eds. HLA 1991. Proceedings of the Eleventh International Histocompatibility Workshop and Conference. Oxford: Oxford University Press; vol 1:397–419.
13. Nevinny-Stickel C, Keller E, Bettinotti MDLP, et al. 1992 Non-radioactive HLA class II typing using polymerase chain reaction, digoxigenin-labeled oligonucleotides, and chemiluminescent detection. In: Tsuji K, Aizawa M, Sasazuki T, eds. HLA 1991. Proceedings of the Eleventh International Histocompatibility Workshop and Conference. Oxford: Oxford University Press; vol2 :302–304.
14. Bodmer JG, Marsh SG, Albert ED, et al. 1997 Nomenclature for factors of the HLA system, 1996. Tissue Antigens. 49:297–321.[Medline]
15. Dittler J, Seidel D, Schenker M, Ziegler A-G. 1998 GADIA2-combi determination as first-line screening for improved prediction of type 1 diabetes in relatives. Diabetes. 47:592–597.[Abstract]
16. Caillat-Zucman S, Djilali-Saiah I, Timsit J, et al. 1997 Insulin dependent diabetes mellitus (IDDM): 12th International Histocompatibility workshop study. In: Charron D, ed. HLA. Proceedings of the Twelfth Histocompatibility Workshop and Conference. Paris: EDK; vol 2:389–398.
17. Vambergue A, Fajardy I, Bianchi F, et al. 1997 Gestational diabetes mellitus and HLA class II (-DQ, -DR) association: The Diagest Study. Eur J Immunogenet. 24:385–394.[Medline]
18. Lohmann T, Seissler J, Verlohren HJ, et al. 1997 Distinct genetic and immunological features in patients with onset of IDDM before and after age 40. Diabetes Care. 20:524–529.[Abstract]
19. Genovese S, Bonfanti R, Bazzigaluppi E, et al. 1996 Association of IA-2 autoantibodies with HLA DR4 phenotypes in IDDM. Diabetologia. 39:1223–1226.[Medline]
20. Sanjeevi CB, Falorni A, Kockum I, Hagopian WA, Lernmark Å. 1996 HLA and glutamic acid decarboxylase in human insulin-dependent diabetes mellitus. Diabetic Med. 13:209–217.[CrossRef][Medline]

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